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Post Info TOPIC: Atoms


L

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Atomic nuclei
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An international team at the ISOLDE radioactive-beam facility at CERN has shown that some atomic nuclei can assume asymmetric, "pear" shapes. The observations contradict some existing nuclear theories and will require others to be amended. The results are published in the journal Nature on 8 May 2013.
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L

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Superatoms
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Researchers Discover Superatoms with Magnetic Shells

A team of Virginia Commonwealth University scientists has discovered a new class of 'superatoms' - a stable cluster of atoms that can mimic different elements of the periodic table - with unusual magnetic characteristics.
The superatom contains magnetised magnesium atoms, an element traditionally considered as non-magnetic. The metallic character of magnesium along with infused magnetism may one day be used to create molecular electronic devices for the next generation of faster processors, larger memory storage and quantum computers.
In a study published online in the Early Edition of the Proceedings of the National Academy of Sciences, the team reports that the newly discovered cluster consisting of one iron and eight magnesium atoms acts like a tiny magnet that derives its magnetic strength from the iron and magnesium atoms. The combined unit matches the magnetic strength of a single iron atom while preferentially allowing electrons of specific spin orientation to be distributed throughout the cluster. 

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L

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RE: Atoms
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Scientists at the Joint Quantum Institute (JQI) in College Park, MD, and the Universidad de Concepción in Chile, have devised a new technique for real-time detection of freely moving individual neutral atoms that is more than 99.7% accurate and sensitive enough to discern the arrival of a single atom in less than one-millionth of a second, about 20 times faster than the best previous methods.
The system, described in Advance Online Publication at the Nature Physics web site by researchers , employs a novel means of altering the polarisation of laser light trapped between two highly-reflective mirrors, in effect letting the scientists "see" atoms passing through by the individual photons that they scatter.
The ability to detect single atoms and molecules is essential to progress in many areas, including quantum information research, chemical detection and biochemical analysis.

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L

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University of Virginia Physicist has Engineered the Classical Picture-Perfect Textbook Atom
It would resemble a miniature solar system - an atomic nucleus orbited by electrons, drawn in nice tidy elliptical orbits - like planets orbiting the Sun. This is a reasonable classical depiction of an atom, but it is completely at odds with the usual quantum description of an atom.
In the quantum energy states of a one-electron atom, the electron does not move in an orbit, but is described by a wave function, which, when squared, produces a probability cloud about the nucleus which does not change in time.
The electron can be in any given place at any given time, and at all places at once. That is quantum mechanics, an arena of physics so strange and complicated, even physicists admit it is hard to picture.

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It has long been known that it is possible to confine electrons or atoms in atomic structures in the same way as sheep can be shut in a pen. Physicists at the Max Planck Institute for Microstructure Physics in Halle have now discovered a strange thing: if the atomic fences have the right shape and the substrate, temperature and other parameters are adjusted appropriately, then randomly vapour-deposited atoms arrange themselves in regular structures within the circular fencing - as if they were sheep arranging themselves neatly in a pen (Physical Review Letters, 2nd November 2006).
For some years, numerous groups of researchers all over the world have been concentrating on forcing conduction electrons (the electrons used for the conduction of electronic current) on the surface of certain materials into patterns using deliberately planted atoms. Their intention is to influence the growth of thin films of material. When new atoms, called adatoms, are vapour-deposited on these electron structures, electrical attraction and repulsion makes them more likely to settle in some areas rather than others, depending on the density of electrons on the material. Physicists hope that they will be able to create thin films of material with predetermined characteristics by tailoring the density of electrons.
The researchers at the Max Planck Institute for Microstructure Physics together with physicists from the University of Halle and the University of Santiago de Compostella in Spain have investigated a special form of electronic structure. They observed electrons in a dense, closed ellipsis of cobalt atoms on a copper substrate. The conduction electrons can be imagined like a gas or a liquid; they form standing waves in circular atomic "pens" similar to waves in a small pond.
The physicists then simulated the effects of vapour-depositing cobalt adatoms. The new atoms interact with the cobalt atoms in the pen and with the enclosed electrons. There are tiny fluctuations in the energy levels which only have an effect at low temperatures of around 10 to 20 kelvins. These fluctuations cause the adatoms to prefer to move to positions with higher densities of electrons, provided the number of vapour-deposited adatoms is correct, the temperature is low enough and the pen sufficiently secure.
The cobalt atoms arrange themselves, so to speak, like the waves in a pond of electrons in ellipses. With adatoms, which can move more easily at lower temperatures, - for example atoms of the element cerium and a circular enclosure, the researchers created regular structures on the circles themselves; this was similar to allowing sheep to run randomly into a pen where they obediently line up, spaced at regular intervals and in concentric circles.
The next step will be to offer experimental proof of the simulations, which should be possible with current atomic scanning force microscopy, and to find new ways to create thin films.

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